Stalk (sheaf) | EPFL Graph Search

Are you an EPFL student looking for a semester project?

Work with us on data science and visualisation projects, and deploy your project as an app on top of GraphSearch.

The stalk of a sheaf is a mathematical construction capturing the behaviour of a sheaf around a given point. Sheaves are defined on open sets, but the underlying topological space consists of points. It is reasonable to attempt to isolate the behavior of a sheaf at a single fixed point of . Conceptually speaking, we do this by looking at small neighborhoods of the point. If we look at a sufficiently small neighborhood of , the behavior of the sheaf on that small neighborhood should be the same as the behavior of at that point. Of course, no single neighborhood will be small enough, so we will have to take a limit of some sort. The precise definition is as follows: the stalk of at , usually denoted , is: Here the direct limit is indexed over all the open sets containing , with order relation induced by reverse inclusion (, if ). By definition (or universal property) of the direct limit, an element of the stalk is an equivalence class of elements , where two such sections and are considered equivalent if the restrictions of the two sections coincide on some neighborhood of . There is another approach to defining a stalk that is useful in some contexts. Choose a point of , and let be the inclusion of the one point space into . Then the stalk is the same as the sheaf . Notice that the only open sets of the one point space are and , and there is no data over the empty set. Over , however, we get: For some categories C the direct limit used to define the stalk may not exist. However, it exists for most categories which occur in practice, such as the or most categories of algebraic objects such as abelian groups or rings, which are namely cocomplete. There is a natural morphism for any open set containing : it takes a section in to its germ, that is, its equivalence class in the direct limit. This is a generalization of the usual concept of a germ, which can be recovered by looking at the stalks of the sheaf of continuous functions on . The constant sheaf associated to some set (or group, ring, etc).

About this result

This page is automatically generated and may contain information that is not correct, complete, up-to-date, or relevant to your search query. The same applies to every other page on this website. Please make sure to verify the information with EPFL's official sources.

Related publications (1)

Related concepts (13)

Related courses (2)

Related lectures (11)

Resolution (algebra)

In mathematics, and more specifically in homological algebra, a resolution (or left resolution; dually a coresolution or right resolution) is an exact sequence of modules (or, more generally, of s of an ), which is used to define invariants characterizing the structure of a specific module or object of this category. When, as usually, arrows are oriented to the right, the sequence is supposed to be infinite to the left for (left) resolutions, and to the right for right resolutions.

Inverse image functor

In mathematics, specifically in algebraic topology and algebraic geometry, an inverse image functor is a contravariant construction of sheaves; here “contravariant” in the sense given a map , the inverse image functor is a functor from the of sheaves on Y to the category of sheaves on X. The is the primary operation on sheaves, with the simplest definition. The inverse image exhibits some relatively subtle features. Suppose we are given a sheaf on and that we want to transport to using a continuous map .

Germ (mathematics)

In mathematics, the notion of a germ of an object in/on a topological space is an equivalence class of that object and others of the same kind that captures their shared local properties. In particular, the objects in question are mostly functions (or maps) and subsets. In specific implementations of this idea, the functions or subsets in question will have some property, such as being analytic or smooth, but in general this is not needed (the functions in question need not even be continuous); it is however necessary that the space on/in which the object is defined is a topological space, in order that the word local has some meaning.

MATH-510: Algebraic geometry II - schemes and sheaves

The aim of this course is to learn the basics of the modern scheme theoretic language of algebraic geometry.

MATH-436: Homotopical algebra

This course will provide an introduction to model category theory, which is an abstract framework for generalizing homotopy theory beyond topological spaces and continuous maps. We will study numerous

Differentiable inverse rendering based on radiative backpropagation

Wenzel Alban Jakob, Merlin Eléazar Nimier-David

A computer-implemented inverse rendering method is provided. The method comprises: computing an adjoint image by differentiating an objective function that evaluates the quality of a rendered image, image elements of the adjoint image encoding the sensitiv ...

2021

Categories and Functors MATH-436: Homotopical algebra

Explores building categories from graphs and the encoding of information by functors.

Sheafification of Presheaves MATH-510: Algebraic geometry II - schemes and sheaves

Covers the sheafification process of presheaves, emphasizing injectivity and surjectivity.

Sheaves and Modules MATH-510: Algebraic geometry II - schemes and sheaves

Covers sheaves and modules, including morphisms, sheafification, cocalization, and direct image properties.